Skip main navigationJournal menuClose Drawer MenuOpen Drawer Menu
Skip main navigationJournal menuClose Drawer MenuOpen Drawer Menu
Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences
Restricted access

Planetary heat flow measurements

Published:25 October 2005https://doi.org/10.1098/rsta.2005.1664

    Abstract

    The year 2005 marks the 35th anniversary of the Apollo 13 mission, probably the most successful failure in the history of manned spaceflight. Naturally, Apollo 13's scientific payload is far less known than the spectacular accident and subsequent rescue of its crew. Among other instruments, it carried the first instrument designed to measure the flux of heat on a planetary body other than Earth. The year 2005 also should have marked the launch of the Japanese LUNAR-A mission, and ESA's Rosetta mission is slowly approaching comet Churyumov-Gerasimenko. Both missions carry penetrators to study the heat flow from their target bodies. What is so interesting about planetary heat flow? What can we learn from it and how do we measure it?

    Not only the Sun, but all planets in the Solar System are essentially heat engines. Various heat sources or heat reservoirs drive intrinsic and surface processes, causing ‘dead balls of rock, ice or gas’ to evolve dynamically over time, driving convection that powers tectonic processes and spawns magnetic fields. The heat flow constrains models of the thermal evolution of a planet and also its composition because it provides an upper limit for the bulk abundance of radioactive elements. On Earth, the global variation of heat flow also reflects the tectonic activity: heat flow increases towards the young ocean ridges, whereas it is rather low on the old continental shields.

    It is not surprising that surface heat flow measurements, or even estimates, where performed, contributed greatly to our understanding of what happens inside the planets. In this article, I will review the results and the methods used in past heat flow measurements and speculate on the targets and design of future experiments.

    References

    • Aumann H.H, Gillespie C.M& Low F.J. 1969The internal powers and effective temperatures of Jupiter and Saturn. Astrophys. J, 157, L69–L72.doi:10.1086/180388. Crossref, ISIGoogle Scholar
    • Baldwin J.E. 1961Thermal radiation from the moon and the heat flow through the lunar surface. Month. Not. R. Astron. Soc, 122, 513–522. Crossref, ISIGoogle Scholar
    • Banaszkiewicz M, Seiferlin K, Spohn T, Kargl G& Kömle N.I. 1997A new method for the determination of thermal conductivity and thermal diffusivity from linear heat source measurements. Rev. Sci. Instrum, 68, 4184–4190.doi:10.1063/1.1148365. Crossref, ISIGoogle Scholar
    • Bullard E.C. 1939Heat flow in South Africa. Proc. R. Soc. A, 173, 474–502. LinkGoogle Scholar
    • Bullard E. 1954The flow of heat through the floor of the Atlantic Ocean. Proc. R. Soc. A, 222, 408–429. LinkGoogle Scholar
    • Christoffel D.A& Calhaem I.M. 1969A geothermal heat flow probe for in situ measurement of both temperature gradient and thermal conductivity. J. Phys. E Sci. Instrum, 2, 457–465.doi:10.1088/0022-3735/2/6/301. CrossrefGoogle Scholar
    • Dunkle R.V. 1940Heat meters. Bull. Am. Meteorol. Soc, 21, 116–117. Google Scholar
    • Graboske H.C, Olness R.J, Pollack J.B& Grossman A.S. 1975The structure and evolution of Jupiter—the fluid contraction stage. Astrophys. J, 199, 265–281.doi:10.1086/153689. Crossref, ISIGoogle Scholar
    • Hagermann A& Spohn T. 1999A method to invert MUPUS temperature recordings for the subsurface temperature field of P/Wirtanen. Adv. Space Res, 23, 1333–1336.doi:10.1016/S0273-1177(99)00046-0. Crossref, ISIGoogle Scholar
    • Hubbard W.B. 1977The Jovian surface condition and cooling rate. Icarus, 30, 305–310.doi:10.1016/0019-1035(77)90164-6. Crossref, ISIGoogle Scholar
    • Jaeger J.C. 1959Sub-surface temperatures on the moon. Nature, 183, 1316–1317. Crossref, ISIGoogle Scholar
    • Johnson H.P& Hutnak M. 1996Conductive heat flow measured in unsedimented regions of the seafloor. EOS, 77, 321–324. CrossrefGoogle Scholar
    • Johnson T.V, Morrison D, Matson D.L, Veeder G.J, Brown R.H& Nelson R.M. 1984Volcanic hotspots on Io—stability and longitudinal distribution. Science, 226, 134–137. Crossref, PubMed, ISIGoogle Scholar
    • Keihm S.J. 1984Interpretation of the lunar microwave brightness temperature spectrum: feasibility of orbital heat flow mapping. Icarus, 60, 568–589.doi:10.1016/0019-1035(84)90165-9. Crossref, ISIGoogle Scholar
    • Keihm S.J& Langseth M.G. 1975Microwave emission spectrum of the moon—mean global heat flow and average depth of the regolith. Science, 187, 64–66. Crossref, PubMed, ISIGoogle Scholar
    • Kinoshita M. 1996Geothermal surveys on submarine hydrothermal systems using submersibles in Japan. Mar. Geores. Geotechnol, 14, 65–75. Crossref, ISIGoogle Scholar
    • Krotikov V.D& Troitskiĭ V.S. 1964Radio emission and nature of the moon. Soviet Phys. Uspekhi, 6, 841–871. CrossrefGoogle Scholar
    • Lachenbruch A.H. 1968Discussion of the paper by Kenneth Watson, ‘proposed lunar heat flow measurement from a polar orbiting satellite’. J. Geophys. Res, 73, 822–823. Crossref, ISIGoogle Scholar
    • Langseth M.G, Wechsler A.E, Drake E.M, Simmons G, Clark S& Chute J. 1970Apollo 13 lunar heat flow experiment. Science, 168, 211–217. Crossref, PubMed, ISIGoogle Scholar
    • Langseth, M. G., Clark, S. P., Chute, J. L., Keihm, S. J. & Wechsler, A. 1972 Heat-flow experiment. Apollo 15 preliminary science Report. NASA SP 289. Washington, DC. Google Scholar
    • Langseth M, Keihm S& Peters K. 1976Revised lunar heat-flow values.In Proc. 7th Lunar Sci. ConfNew York:Pergamon Press3143–3171. Google Scholar
    • Lawrence D.J, Feldman W.C, Barraclough B.L, Binder A.B, Elphic R.C, Maurice S, Miller M.C& Prettyman T.H. 2000Thorium abundances on the lunar surface. J. Geophys. Res, 105, 20 307–20 331.doi:10.1029/1999JE001177. Crossref, ISIGoogle Scholar
    • Lehmann P. 1952Ein Integrator für Wärmeumsatzmessungen im Boden. Berichte d. dt. Wetterdienstes in d. US-Zone, 35, 304–306. Google Scholar
    • Lister C.R.B. 1970Measurement of the in situ sediment conductivity by means of a Bullard-type probe. Geophys. J. R. Astron. Soc, 19, 521–532. Crossref, ISIGoogle Scholar
    • Lister C.R.B. 1972On the thermal balance of a mid-ocean ridge. Geophys. J. R. Astron. Soc, 26, 515–535. Crossref, ISIGoogle Scholar
    • Luu J.X& Jewitt D.C. 1990Cometary activity in 2060 Chiron. Astron. J, 100, 913–932.doi:10.1086/115571. Crossref, ISIGoogle Scholar
    • Marczewski W, et al.2004Prelaunch performance evaluation of the cometary experiment MUPUS-TP. J. Geophys. Res, 109, E07S09. doi:10.1029/2003JE002192. Crossref, ISIGoogle Scholar
    • Matson D.L, Ransford G.A& Johnson T.V. 1981Heat flow from Io/JI/. J. Geophys. Res, 86, 1664–1672. Crossref, ISIGoogle Scholar
    • Matson D.L, Johnson T.V, Veeder G.J, Blaney D.L& Davies A.G. 2001Upper bound on Io's heat flow. J. Geophys. Res, 106, 33 021–33 024.doi:10.1029/2000JE001374. Crossref, ISIGoogle Scholar
    • Mizutani H. 1995Lunar interior exploration by Japanese lunar penetrator mission, LUNAR-A. J. Phys. Earth, 43, 657–670. CrossrefGoogle Scholar
    • Mizutani H, Fujimura A, Hayakawa M, Tanaka S, Shiraishi H& Yoshida S. 2000LUNAR-A mission: science objectives and instruments.In ESA SP-462: exploration and utilisation of the Moonpp. 107–114. Google Scholar
    • Mizutani H, Fujimura A, Tanaka S, Shiraishi H& Nakajima T. 2003LUNAR-A mission: goals and status. Adv. Space Res, 31, 2315–2321.doi:10.1016/S0273-1177(03)00542-8. Crossref, ISIGoogle Scholar
    • Morrison D& Telesco C.M. 1980Io—observational constraints on internal energy and thermophysics of the surface. Icarus, 44, 226–233.doi:10.1016/0019-1035(80)90018-4. Crossref, ISIGoogle Scholar
    • Nozette S, Lichtenberg C.L, Spudis P, Bonner R, Ort W, Malaret E, Robinson M& Shoemaker E.M. 1996The Clementine bistatic radar experiment. Science, 274, 1495–1498.doi:10.1126/science.274.5292.1495. Crossref, PubMed, ISIGoogle Scholar
    • Peale S.J, Cassen P& Reynolds R.T. 1979Melting of Io by tidal dissipation. Science, 203, 892–894. Crossref, PubMed, ISIGoogle Scholar
    • Pollack J.B, Grossman A.S, Moore R& Graboske H.C. 1977A calculation of Saturn's gravitational contraction history. Icarus, 30, 111–128.doi:10.1016/0019-1035(77)90126-9. Crossref, ISIGoogle Scholar
    • Pollack H.N, Hurter S.J& Johnson J.R. 1993Heat flow from the Earth‘s interior: analysis of the global data set. Rev. Geophys, 31, 267–280.doi:10.1029/93RG01249. Crossref, ISIGoogle Scholar
    • Rasmussen K.L& Warren P.H. 1985Megaregolith thickness, heat flow, and the bulk composition of the moon. Nature, 313, 121–124.doi:10.1038/313121a0. Crossref, ISIGoogle Scholar
    • Revelle R& Maxwell A.E. 1952Heat flow through the floor of the eastern North Pacific Ocean. Nature, 170, 199–200. Crossref, ISIGoogle Scholar
    • Salpeter E.E. 1973On convection and gravitational layering in Jupiter and in stars of low mass. Astrophys. J, 181, L83–L86.doi:10.1086/181190. Crossref, ISIGoogle Scholar
    • Sclater J.G, Jaupart C& Galson D. 1980The heat flow through oceanic and continental crust and the heat loss of the earth. Rev. Geophys. Space Phys, 18, 269–311. Crossref, ISIGoogle Scholar
    • Sclater J.G, Parsons B& Jaupart C. 1981Oceans and continents: similarities and differences in the mechanisms of heat loss. J. Geophys. Res, B12, 11 535–11 552. Crossref, ISIGoogle Scholar
    • Segatz M, Spohn T, Ross M.N& Schubert G. 1988Tidal dissipation, surface heat flow, and figure of viscoelastic models of Io. Icarus, 75, 187–206.doi:10.1016/0019-1035(88)90001-2. Crossref, ISIGoogle Scholar
    • Seiferlin K, Hagermann A, Banaszkiewicz M& Spohn TUsing penetrators as thermal probes: the MUPUS case. , Kömle N, Kargl G, Ball A.J& Lorenz R.DIn Penetrometry in the solar system2001aVienna:Verlag der Österreichischen Akademie der Wissenschaften161–184. Google Scholar
    • Seiferlin K, Spohn T, Ball A.J, Kargl G, Kömle N& Hagermann AThermal inertia and cohesion of Martian soil: scientific aspects of the SPICE experiment on netlander. Geophys. Res. Abstr, 32001b7206. Google Scholar
    • Shen P& Beck A. 1991Least squares inversion of borehole temperature measurements in functional space. J. Geophys. Res, B12, 19 965–19 979. Crossref, ISIGoogle Scholar
    • Spencer J.R, Rathbun J.A, Travis L.D, Tamppari L.K, Barnard L, Martin T.Z& McEwen A.S. 2000Io's thermal emission from the galileo photopolarimeter—radiometer. Science, 288, 1198–1201.doi:10.1126/science.288.5469.1198. Crossref, PubMed, ISIGoogle Scholar
    • Spohn T. 1991Mantle differentiation and thermal evolution of Mars, Mercury, and Venus. Icarus, 90, 222–236.doi:10.1016/0019-1035(91)90103-Z. Crossref, ISIGoogle Scholar
    • Spohn T, Banaszkiewicz M, Benkhoff J, Ip W.H, Jaupart C, Kömle N, Kührt E, Leese M& McDonnell T. 1995MUPUS, proposal for a suite of instruments to make extended in situ physical measurements at the surface of an evolving comet nucleus.In Experiment proposalMünster:Institut für Planetologie. Google Scholar
    • Spohn T, Ball A.J, Seiferlin K, Conzelmann V, Hagermann A, Kömle N.I& Kargl G. 2001A heat flow and physical properties package for the surface of mercury. Planet. Space Sci, 49, 1571–1577.doi:10.1016/S0032-0633(01)00094-0. Crossref, ISIGoogle Scholar
    • Staley R& Gerhardt G. 1957Soil heat flux measurements. , Lettau M& Davidson BIn Exploring the atmosphere's 1st mileNew York:Pergamon Press59–63. Google Scholar
    • Stevenson D.J& Salpeter E.E. 1977The dynamics and helium distribution in hydrogen–helium fluid planets. Astrophys. J, 35, 239–261.doi:10.1086/190479. Crossref, ISIGoogle Scholar
    • Surkov Y.A, Kremnev R.S, Pichkhadze K.M& Akulov Y.P. 2001Penetrators for exploring solar system bodies. , Kömle N, Kargl G, Ball A.J& Lorenz R.DIn Penetrometry in the solar systemVienna:Verlag der Österreichischen Akademie der Wissenschaften185–196. Google Scholar
    • Tanaka S, Yoshida S, Hayakawa M, Fujimura A& Mizutani H. 2000Thermal modelling of the LUNAR-A penetrator and its effects on the accuracy for lunar heat flow experiment.In ESA SP-462: exploration and utilisation of the Moonpp. 187–190. Google Scholar
    • van der Held E.F.M& van Drunen F.G. 1949A method of measuring the thermal conductivity of liquids. Physica, 15, 865–881.doi:10.1016/0031-8914(49)90129-9. CrossrefGoogle Scholar
    • Veeder G.J, Matson D.L, Johnson T.V, Blaney D.L& Goguen J.D. 1994Io's heat flow from infrared radiometry: 1983–1993. J. Geophys. Res, 99, 17 095–17 162.doi:10.1029/94JE00637. Crossref, ISIGoogle Scholar
    • von Herzen R& Maxwell A.E. 1959The measurement of thermal conductivity of deep-sea sediments by a needle-probe method. J. Geophys. Res, 64, 1557–1563. CrossrefGoogle Scholar
    • Wang K. 1992Estimation of ground surface temperatures from borehole temperature data. J. Geophys. Res, 97, 2095–2106. Crossref, ISIGoogle Scholar
    • Warren P.H& Rasmussen K.L. 1987Megaregolith insulation, internal temperatures and bulk uranium content of the Moon. J. Geophys. Res, 92, 3453–3465. Crossref, ISIGoogle Scholar
    • Watson K. 1967Proposed lunar heat flow measurement from a polar orbiting satellite. J. Geophys. Res, 72, 3301–3302. Crossref, ISIGoogle Scholar
    • Yoshida S, Tanaka S, Hagermann A, Hayakawa M, Fujimura A& Mizutani H. 2001Derivation of globally averaged lunar heat flow from the local heat flow values and the thorium distribution at the surface: expected improvement by the LUNAR-A mission. Lunar Planet. Sci, XXXII, 1571–1572. Google Scholar
    Previous Article
    Next Article